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A Practical Framework for the Construction of a Biotracing Model: Application to Salmonella in the Pork Slaughter Chain

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  • J. H. Smid
  • A. N. Swart
  • A. H. Havelaar
  • A. Pielaat

Abstract

A novel purpose of the use of mathematical models in quantitative microbial risk assessment (QMRA) is to identify the sources of microbial contamination in a food chain (i.e., biotracing). In this article we propose a framework for the construction of a biotracing model, eventually to be used in industrial food production chains where discrete numbers of products are processed that may be contaminated by a multitude of sources. The framework consists of steps in which a Monte Carlo model, simulating sequential events in the chain following a modular process risk modeling (MPRM) approach, is converted to a Bayesian belief network (BBN). The resulting model provides a probabilistic quantification of concentrations of a pathogen throughout a production chain. A BBN allows for updating the parameters of the model based on observational data, and global parameter sensitivity analysis is readily performed in a BBN. Moreover, a BBN enables “backward reasoning” when downstream data are available and is therefore a natural framework for answering biotracing questions. The proposed framework is illustrated with a biotracing model of Salmonella in the pork slaughter chain, based on a recently published Monte Carlo simulation model. This model, implemented as a BBN, describes the dynamics of Salmonella in a Dutch slaughterhouse and enables finding the source of contamination of specific carcasses at the end of the chain.

Suggested Citation

  • J. H. Smid & A. N. Swart & A. H. Havelaar & A. Pielaat, 2011. "A Practical Framework for the Construction of a Biotracing Model: Application to Salmonella in the Pork Slaughter Chain," Risk Analysis, John Wiley & Sons, vol. 31(9), pages 1434-1450, September.
    • Handle: RePEc:wly:riskan:v:31:y:2011:i:9:p:1434-1450
    DOI: 10.1111/j.1539-6924.2011.01591.x
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